IMECH-IR  > 流固耦合系统力学重点实验室
A theoretical model to estimate inactivation effects of OH radicals on marine Vibrio sp. in bubble-shock interaction
Huang Y; Wang J; Abe A; Wang YW(王一伟); Du TZ(杜特专); Huang CG(黄晨光)
Corresponding AuthorWang, J.(wangjingzhu@imech.ac.cn) ; Wang, Y.(wangyw@imech.ac.cn)
Source PublicationULTRASONICS SONOCHEMISTRY
2019-07-01
Volume55Pages:359-368
ISSN1350-4177
AbstractA theoretical model for estimating inactivation effects on marine Vibrio sp. is developed from the viewpoint of the chemical action of the OH radicals induced by interaction of bubbles with shock waves. It consists of a biological probability model for cell viability and a bubble dynamic model for its collapsing motion due to the shock pressures. The biological probability model is built by defining a sterilized space of the OH radicals. To determine the radius of the sterilized space, the Herring equation is solved in the bubble dynamic model in consideration of the effect of the heat conductivity and mass transportation. Furthermore, the pressure waveform of incident shock wave used in the model is obtained with the pressure measurement. On the other hand, a bio-experiment of marine Vibrio sp. is carried out using a high-voltage power supply in a cylindrical water chamber. Finally, the viability ratio of marine bacteria estimated by the theoretical model is examined under the experimental conditions of this study. In addition, we also discuss the influence of bubble initial size for predicting the inactivation effects.
KeywordTheoretical model Bubble-shock interaction Chemical inactivation Biological probability model Generation and diffusion of OH radicals
DOI10.1016/j.ultsonch.2018.10.001
Indexed BySCI ; EI
Language英语
WOS IDWOS:000470047800039
WOS KeywordWAVE LITHOTRIPSY SWL ; SONOLYTIC DEGRADATION ; MECHANICAL HEMOLYSIS ; WATER-VAPOR ; FREQUENCY ; STERILIZATION ; TEMPERATURE ; PRESSURE ; SONOLUMINESCENCE ; MICROBUBBLES
WOS Research AreaAcoustics ; Chemistry
WOS SubjectAcoustics ; Chemistry, Multidisciplinary
Funding ProjectNational Natural Science Foundation of China[11802311] ; National Natural Science Foundation of China[11772340] ; National Natural Science Foundation of China[11672315] ; Youth Innovation Promotion Association CAS[2015015] ; JSPS KAKENHI[16H04600and 16K14512]
Funding OrganizationNational Natural Science Foundation of China ; Youth Innovation Promotion Association CAS ; JSPS KAKENHI
Classification一类
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Document Type期刊论文
Identifierhttp://dspace.imech.ac.cn/handle/311007/79347
Collection流固耦合系统力学重点实验室
Recommended Citation
GB/T 7714
Huang Y,Wang J,Abe A,et al. A theoretical model to estimate inactivation effects of OH radicals on marine Vibrio sp. in bubble-shock interaction[J]. ULTRASONICS SONOCHEMISTRY,2019,55:359-368.
APA Huang Y,Wang J,Abe A,王一伟,杜特专,&黄晨光.(2019).A theoretical model to estimate inactivation effects of OH radicals on marine Vibrio sp. in bubble-shock interaction.ULTRASONICS SONOCHEMISTRY,55,359-368.
MLA Huang Y,et al."A theoretical model to estimate inactivation effects of OH radicals on marine Vibrio sp. in bubble-shock interaction".ULTRASONICS SONOCHEMISTRY 55(2019):359-368.
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